JP6539136B2 - refrigerator - Google Patents

Description

  The present invention relates to a refrigerator.

  In a refrigerator, when putting food etc. in the pulled out storage container or taking out food etc. from the storage container, the opening of the storage container pulled out is wide from the viewpoint of easiness of putting in and out of the storage container. It is preferable to be provided. Then, the technique of patent document 1 is known as a technique which enlarges the amount of drawers of a door.

  Patent Document 1 discloses a frame for supporting a storage case (storage container), a guide groove formed at the rear of the frame and extending in the front and back direction facing the side wall of the storage chamber, and the inside of the guide groove A refrigerator is described which comprises a sliding slider, a moving roller pivotally supported by a horizontal shaft at the rear of the slider, and a fixed rail extending forward and backward on the side wall of the storage room to guide the moving roller. .

JP, 2009-14266, A

  However, when the amount of withdrawal of the door is increased in order to widen the opening of the storage container (full opening), when the weight of the stored goods in the storage container is large, the frame supporting the storage container is twisted, There is a problem that the door goes down.

  This invention solves the said conventional problem, and it aims at providing the refrigerator which can suppress the fall of a door when a door is pulled out.

The present invention comprises a storage room, a storage container stored in the storage room, a storage container drawer storage mechanism for pulling out the storage container from the storage room, and storing the storage container in the storage room. In the refrigerator, the storage container drawer storage mechanism includes a storage chamber rail provided in the storage chamber and extending in the front-rear direction, a frame member supporting the storage container, and an inner extending along the storage chamber rail. The inner member and the outer member can be moved independently by rotating while contacting the member, the outer member arranged to face the inner member, and both the inner member and the outer member. A slide rail including a rolling element, and a support for movably supporting the frame member in the front-rear direction while being in contact with the frame member, One of the inner member and the outer member is fixed to the frame member, and the fixing portion fixed to the frame member is a region where the inner member and the outer member overlap when the storage container is pulled out to the maximum. And at least a part of the fixed part is located on the vertical projection of the support or behind the support when the storage container is pulled out to the maximum .

  ADVANTAGE OF THE INVENTION According to this invention, the refrigerator which can suppress the fall of a door when pulling out a door can be provided.

It is a front view of the refrigerator of 1st Embodiment. It is a perspective view when a storage container is pulled out from a vegetable room to the maximum. It is a longitudinal cross-sectional view when a storage container is pulled out most from a vegetable compartment. It is a perspective view when the flame | frame which supports a storage container is seen from the back right side. It is a perspective view when the flame | frame which supports a storage container is seen from the back left side. It is a perspective view which shows the state which pulled out the flame | frame from the vegetable compartment to the maximum. It is a perspective view which shows a mode when a flame | frame is accommodated in a vegetable compartment. It is an exploded perspective view showing a frame member and a slide rail. It is a side view which shows the frame member and the slide rail after assembly. It is the sectional view on the AA line of FIG. It is a perspective view when the rear end of the member of FIG. 9 is seen from a frame bearing side. It is a side view when the rear end of the member of FIG. 9 is seen from the frame member side. The box side rail provided in the storage chamber side is shown, (a) is a perspective view, (b) is a BB sectional view of (a), (c) is a CC sectional view of (a), d) is a cross-sectional view taken along the line D-D of (a). It is sectional drawing which shows the structure of a frame member, a slide rail, and a box side rail. It is the EE sectional view taken on the line of FIG. It is operation | movement explanatory drawing at the time of pulling out a storage container from a vegetable compartment, (a) is a state which the frame bearing contact | abutted to the stopper member, (b) is the state which the frame member contact | abutted to the box bearing. It is a longitudinal cross-sectional view when a storage container is pulled out to the front side as much as possible. It is a side view which shows 2nd Embodiment of the fixing method of a frame member and an inner member.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings as appropriate. In the drawings referred to as appropriate, the illustration of the storage container 101 may be omitted unless otherwise specified, for simplification of the illustration. Moreover, the full open in the following description means the state by which the whole storage container 101 is pulled out from the vegetable compartment 100 (storage room) (refer FIG. 3).

  FIG. 1 is a front view of the refrigerator 10 according to the first embodiment. The refrigerator 10 shown in FIG. 1 includes a refrigerator compartment left door 2, a refrigerator compartment right door 3, an ice making room door 4a, a rapid freezing room door 4b, a freezing room door 5, and a vegetable room on the front of the refrigerator body 1. The door 6 is provided. The cold storage room left door 2 is rotatable in the front side of the drawing by the upper hinge 7a and the lower hinge 8a. Furthermore, the refrigerator compartment right door 3 is rotatable in the front side of the drawing by the upper hinge 7b and the lower hinge 8b. That is, the cold storage room left door 2 and the cold storage room right door 3 are provided so as to be capable of double opening, and a cold storage room (not shown) is formed in the space formed by these and the refrigerator main body 1.

  In addition, the ice making room door 4a, the rapid freezing room door 4b and the freezing room door 5 can be pulled out in the front side of the drawing. And, in the space formed by these and the refrigerator main body 1, an ice making room, a quick freezing room and a freezing room (all not shown) are respectively formed. Similarly, the vegetable compartment door 6 can be pulled out in the front direction of the drawing. Furthermore, a vegetable room 100 (a vegetable room where stored products such as vegetables are stored, see FIG. 4) is formed in a space constituted by this and the refrigerator main body 1.

FIG. 2 is a perspective view when the storage container is maximally pulled out of the vegetable compartment. In addition to vegetables and the like being stored in the storage container 101, bottled beverages and the like are stored.
As shown in FIG. 2, in the vegetable compartment 100, the inner box 124 of the refrigerator body 1 constitutes the wall of the vegetable compartment 100 (left wall 100a, right wall 100b, bottom wall 100c and rear wall 100d). Moreover, the upper wall of the vegetable compartment 100 is comprised by the heat insulation partition wall (not shown) which divides the vegetable compartment 100 and a freezer compartment (not shown). Therefore, in the vegetable compartment 100, the sealing property of the vegetable compartment 100 is ensured by the wall surfaces (the left wall 100a, the right wall 100b, the bottom wall 100c and the rear wall 100d), the upper wall (not shown) and the vegetable compartment door 6.

  In the vegetable room 100, the storage container 101 is accommodated in the front side and the back side so as to be freely extractable (hereinafter, sometimes referred to as "in the front-rear direction"). The storage container 101 is configured of a lower container 102 and an upper container 103. The upper container 103 is disposed at the top of the lower container 102. Further, a lock handle 106 is provided on the upper container 103, and the user can lock the lock handle 106 so that the upper container 103 can move in the front-rear direction together with the lower container 102. In addition, the unlocking operation of the lock handle 106 enables the upper container 103 to move in the front-rear direction while maintaining the position of the lower container 102.

  Moreover, the collar part 102a extended in the front-back direction is formed in the left-right-both-sides part of the lower stage container 102 (only the right side is shown), This collar part 102a is contact | abutted to the frame member 180 (storage container drawer accommodation mechanism) mentioned later. It is supported. Further, the left and right side portions of the upper container 103 are formed with hook portions 103a extending in the front and rear direction (only the right side is shown), and the hook portions 103a are movable in the front and rear direction over the hook portion 102a of the lower container 102. ing.

FIG. 3 is a vertical cross-sectional view when the storage container is pulled out of the vegetable compartment at maximum.
As shown in FIG. 3, on the back side of the vegetable compartment 100, a machine compartment 107 for forming a compressor (not shown) or the like outside the storage compartment is formed. In addition, a cold air outlet (not shown) for cooling the inside of the lower container 102 and the upper container 103 is disposed on the back side (rear side) of the vegetable room 100. The lower container 102 is provided with a glass partition 104. Thus, the lower container 102 is divided into two front and rear sections. The upper container 103 is disposed so as to cover the upper space on the back side of the two sections of the lower container 102.

4 and 5 are perspective views of the frame 161 supporting the storage container 101. FIG.
In FIGS. 4 and 5, the storage container 101 (not shown) is supported by the frame 161 so as to sandwich the left and right side surfaces thereof. The frame 161 includes a pair of left and right frame members 180 extending in the front and rear direction (front and rear surfaces), and a substantially U-shaped connection member 166 connecting the left frame member 180 and the right frame member 180. , And a rod-like cross frame 167 for connecting the left and right slide rails 179 (storage container drawer storage mechanism) to be described later.

  Further, the frame member 180 is provided with a slide rail 179 for moving the storage container 101 in the front-rear direction. The slide rail 179 is fixed to the frame member 180. As the slide rail 179 extends and contracts in the front-rear direction, the storage container 101 is pulled out and stored. The details of the configuration of the slide rail 179 will be described later.

  The connection members 166 are fixed to the left and right frame members 180 via the frame fixing portions 169, and the frame members 180 are configured together with the cross frame 167. Furthermore, on the front side of the frame member 180, a door fixing portion 162 for fixing the vegetable compartment door 6 is provided. When the user pulls out or pushes the vegetable compartment door 6 attached to the door fixing part 162 to the front side, the storage container 101 is pulled out from the vegetable compartment 100 or accommodated in the vegetable compartment 100. ing.

  The connection member 166 has a bottom plate 166a for supporting the bottom surface of the storage container 101 (not shown), and side plates 166b and 166b extending upward from the left and right ends of the bottom plate 166a along the left and right sides of the storage container 101. Thus, the storage container 101 is supported by the frame member 180 and the connection member 166. In addition, in the storage container 101, the movement in the front-rear direction is restricted by fitting a protrusion (not shown) formed on the collar 102a (see FIG. 2) into the hole 180m formed on the frame member 180. It is supposed to be.

  Further, on the back surface side (rear end portion) of the slide rail 179, a transverse frame 167 is attached so as to connect the left and right slide rails 179. By providing the cross frame 167, the slide rail 179 is prevented from falling inward.

FIG. 6 is a perspective view showing a state in which the frame is pulled out of the vegetable compartment to the maximum.
As shown in FIG. 6, a container driving mechanism 200 for supporting the movement of the storage container 101 in the front-rear direction is connected to the connection portion 168 (see FIGS. 4 and 5) provided on the frame 161. . The container driving mechanism 200 is an electric type, and when the user depresses the open switch 201, a force necessary for the storage container 101 to move to the front side is received via the connection portion 168. It is given to

  The container driving mechanism 200 does not apply force to the storage container 101 in all sections while the storage container 101 and the like are moving, and the front side of the storage container 101 is only once after the user presses the open switch 201 or the like. The power to move to is given. That is, a force to the extent that the storage container 101 can be pulled out completely to the front side by the frame member 180 is given to the storage container 101 only once. Thus, the user can easily stop the storage container 101 at a desired position while the storage container 101 is being pulled out.

  FIG. 7 is a perspective view showing how the frame is accommodated in the vegetable compartment. Although not shown in FIG. 7 for simplification, in actuality, the frame 161 and the storage container 101 are stored in the vegetable compartment 100 in a state where the storage container 101 is supported by the frame 161. The slide rails 179 are movable along box side rails 178 (a storage room rail, a storage container drawer accommodation mechanism, only the left side is illustrated) provided on the left and right sides of the inner box 124. In addition, the slide rail 179 moves in the front-rear direction together with the frame member 180, whereby the storage container 101 can be pulled out and stored. The detailed configuration of the box side rail 178 will be described later with reference to FIG.

FIG. 8 is an exploded perspective view showing the frame member and the slide rail. The left and right frame members 180 and the left and right slide rails 179 have a left-right symmetrical shape (see FIGS. 4 and 5), and therefore, the left and right frame members 180 and slide rails 179 will be described below.
As shown in FIG. 8, the slide rail 179 includes an outer member 184, an inner member 185, balls 188 (rolling elements), and a retainer 191.

  The outer member 184 has a side surface portion 184 a extending in the front-rear direction, and an upper surface portion 184 b and a lower surface portion 184 c on which the ball 188 abuts. Further, the outer member 184 is formed with a cut-and-raised stopper 184 d at the front end (front side) of the side surface portion 184 a.

  In addition, a connecting member 192 to which a frame bearing 181 (see FIGS. 4 and 5) and a cross frame 167 (see FIGS. 4 and 5) are attached is connected to the rear end (rear side) of the outer member 184. At the rear end of the outer member 184, through holes 184e through which the rivets 193 and 193 are inserted are formed in line in the front-rear direction. The rivets 193 are assumed to be, for example, blind rivets, but not limited to rivets, and may be screws or spot welds.

  The connecting member 192 is formed in a substantially rectangular shape in a side view, and is attached to the outer member 184 so as to be disposed at a position facing the rear end 180s of the frame member 180. Further, through holes 192a and 192a are formed in the connecting member 192 at positions corresponding to the through holes 184e and 184e. In the present embodiment, the connecting member 192 is attached to the outer member 184 in consideration of the strength as a top priority. However, the connecting member 192 may be attached to the inner member 185 in reverse.

  The inner member 185 is disposed to face the outer member 184, and has a side surface portion 185a extending in the front-rear direction, and an upper surface portion 185b and a lower surface portion 185c with which the ball 188 abuts. In the side surface portion 185a, a stopper 185s cut and raised on the outer member 184 side is formed in the vicinity of the rear end. Further, the front end 185 u of the inner member 185 is formed bent on the outer member 184 side.

  Further, in the side surface portion 185a, through holes 185d through which the rivets 187 (storage container drawing and storing mechanism) are inserted are formed at a plurality of places (four places in the present embodiment) at intervals in the front-rear direction. In the through holes 185d, the distance on the front side is wide, and the distance on the rear side is narrower than the front.

  In the side surface portion 185a, a positioning convex portion 185e for positioning is formed between the first through hole 185d and the second through hole 185d from the front side. Further, on the surface of the side surface portion 185a on the side of the frame member 180, positioning convex portions 185e, 185e for positioning are formed between the second through hole 185d and the third through hole 185d with an interval in the front and rear direction. It is done.

  A plurality of balls 188 are held side by side in the front-rear direction between the upper surface portion 184 b of the outer member 184 and the upper surface portion 185 b of the inner member 185. In addition, a plurality of balls 188 are held side by side in the front-rear direction between the lower surface portion 184 c of the outer member 184 and the lower surface portion 185 c of the inner member 185. Each ball 188 rotates while being in contact with both the inner member 185 and the outer member 184, thereby enabling the inner member 185 and the outer member 184 to move independently. A roller may be applied instead of the ball 188 as a rolling element.

  The retainer 191 rotatably holds the balls 188, and has holes 189a for holding the balls 188 independently at the top and bottom. Further, the retainer 191 is formed to have a length approximately half that of the outer member 184 in the longitudinal direction.

  Since the slide rail 179 is configured to include the independently movable inner member 185 and the outer member 184 in this manner, a larger amount of withdrawal of the storage container 101 is secured. That is, although details will be described later, after the inner member 185 and the outer member 184 are integrally moved to the front side first, only the inner member 185 is moved to the front side in the front side from the predetermined position. A larger amount of withdrawal of the container 101 is secured.

  The frame member 180 includes a side surface portion 180a extending along the front-rear direction, an upper surface portion 180b bent toward the inner member 185 at the upper edge of the side surface portion 180a, and a bending toward the inner member 185 at the lower edge of the side surface portion 180a. And a lower surface portion 180c (see FIG. 5) to be formed.

  A through hole 180d through which a rivet 187 is inserted is formed in the side surface portion 180a at a position corresponding to the through hole 185d. Further, positioning concave portions (holes) 180 e are formed in the side surface portion 180 a at positions corresponding to the positioning convex portions 185 e described above.

  In the slide rail 179 and the frame member 180 configured as described above, the positioning convex portion 185e is engaged with the positioning concave portion (hole) 180e and positioned. Then, the rivets 187 are inserted through the through holes 180 d of the frame member 180 and the through holes 185 d of the inner member 185, and the inner member 185 is fixed (crimped) to the frame member 180 by using equipment for the rivets 187. Thus, the inner member 185 and the frame member 180 are fixed such that the rear end 185t of the inner member 185 and the rear end 180s of the frame member 180 are substantially flush with each other. The outer member 184 is slidable in the front-rear direction with respect to the inner member 185 and the frame member 180.

  FIG. 9 is a side view showing the frame member and the slide rail after assembly, and FIG. 10 is a cross-sectional view taken along line AA of FIG. In addition, in FIG. 9, illustration of the buffer member 197 attached to the connection member 192 to be described later is omitted.

  As shown in FIG. 9, in the frame member 180, a rib (reinforcing portion) 180f (for enhancing rigidity) for reinforcing the frame member 180 at a corner which is a boundary between the side surface portion 180a and the lower surface portion 180c. Are formed at a plurality of places (6 places in the present embodiment). Further, the rib 180 f is formed closer to the rear than the center in the front-rear direction of the frame member 180.

  Further, the distance in the front-rear direction between the rearmost rib 180f and the second rear rib 180f is smaller than the distance between the other ribs 180f and 180f. Thus, by forming the ribs 180f in the frame member 180, the rigidity of the frame member 180 is improved, and the frame member 180 receives the load of the storage container 101 when the vegetable compartment door 6 is fully opened (full open). It is possible to reduce the twisting of the frame member 180 caused by this.

  In addition, the box bearing 182 (support, storage container drawer accommodation mechanism, see FIG. 3) contacts the rear end of the lower surface portion 180c of the frame member 180 at the time of full opening, and regulates the withdrawal operation of the vegetable compartment door 6 A protrusion 176 is formed. In the vicinity of the protrusion 176, the ribs 180f and 180f described above are arranged close to each other.

  In the present embodiment, although the rib 180f is described as an example of the reinforcing portion, the present invention is not limited to the rib 180f, and (1) the material strength of the frame member 180 may be increased. ) The plate thickness of the frame member 180 may be increased, (3) another member may be attached to the frame member 180 by spot welding, and (4) the frame member 180 is divided and configured, the rear end The side plate thickness or material strength may be increased, or these may be combined.

  As shown in FIG. 10, the inner member 185 is fixed to the frame member 180 through the rivets 187. In addition, in FIG. 10, the rivet 187 before fixing is shown collectively. Further, although not shown, the rivets 187 in other places are similarly configured.

  The rivet 187 is configured of a hollow rivet having a cylindrical hollow portion 187a formed at the tip. The rivets 187 are inserted into the through holes 180 d of the frame member 180 and the through holes 185 d of the inner member 185, and then spread so that the tip of the hollow portion 187 a protruding from the through holes 185 d is pressed against the opening edge. Then, the frame member 180 and the inner member 185 are joined.

  By the way, when the frame member 180 and the inner member 185 are fixed by rivets, if the protrusion of the rivet from the inner member 185 is large, it may contact the retainer 191 and the slide function in the slide rail 179 may not work. Furthermore, it is also necessary to secure connection strength when fixing the frame member 180 and the inner member 185. That is, it is necessary to realize space saving while maintaining strength, and in the present embodiment, hollow rivets are used. However, if there is sufficient strength or space, for example, they may be fixed using screws, may be connected using welding, or may be connected by caulking.

  Therefore, in the present embodiment, by employing a hollow rivet as the rivet 187, the amount of protrusion of the rivet 187 from the inner member 185 can be reduced (see FIG. 10), so that the rivet 187 is prevented from contacting the retainer 191. be able to. Furthermore, the use of hollow rivets enables a firm connection.

FIG. 11 is a perspective view of the member of FIG. 9 as viewed from the frame bearing side.
As shown in FIG. 11, a frame bearing 181 is rotatably supported on the right side surface of the connection member 192. The axial direction of the rotation axis (central axis) 181 a of the frame bearing 181 is in the left-right direction. Further, the frame bearing 181 is configured, for example, by using polyacetal resin for the outer race and using steel for the ball and the inner race.

  The frame bearing 181 is movable in the front-rear direction along the box-side rail 178 while rotating in the groove 189 formed in the box-side rail 178. Therefore, the outer member 184 (slide rail 179) moves in the front-rear direction by moving the frame bearing 181 in the front-rear direction while rotating.

  Also, a buffer member 197 is fixed to the upper part of the connection member 192 via a screw 198. The buffer member 197 is formed of a synthetic resin or the like, and a back surface portion 197a located on the back surface side (rear surface side) of the connection member 192, an upper surface portion 197b located on the top surface side of the connection member 192, and a front surface of the connection member 192. And a front portion 197c located on the side. The connecting member 192 is not limited to a synthetic resin, and may be another material such as rubber.

FIG. 12 is a side view when the rear end of the member of FIG. 9 is viewed from the frame member side.
As shown in FIG. 12, the front surface portion 197 c of the buffer member 197 is located at a height facing the upper portion of the rear end 180 s of the frame member 180. As a result, when the frame member 180 and the connecting member 192 come closest to each other, the rear end 180s of the frame member 180 and the buffer member 197 contact each other, so the stopper 184d (see FIG. 8) and the front end 185u (see FIG. 8) Can be prevented from colliding. As described above, since the buffer member 197 and the frame member 180 collide with each other, the collision noise (noise) and the vibration can be reduced as compared with the case where the stopper 184 d and the front end 185 u collide with each other.

Fig. 13 shows a box side rail provided on the storage chamber side, (a) is a perspective view, (b) is a cross-sectional view taken along the line B-B of (a), (c) is a line taken along the line C-C of (a) Sectional drawing, (d) is the DD sectional view taken on the line of (a).
As shown in FIG. 13A, the box side rail 178 is formed with a groove 189 which is guided in the front-rear direction while the frame bearing 181 (see FIG. 11) rotates. A guide wall 190 is formed on the outside of the groove 189 (on the right side in FIG. 13A) to prevent the frame bearing 181 from coming off halfway. However, when molding the box side rail 178, it is difficult to form the guide wall 190 in the vicinity of the back side end 178b. Therefore, in order to prevent the frame bearing 181 from being detached from the portion where the guide wall 190 is not provided, a rib 186 is formed to prevent the frame bearing 181 from reaching the portion where the guide wall 190 is not provided. That is, on the back surface side (rear end) of the box side rail 178, a rib 180f is formed for restricting the movement of the frame bearing 181 which rotationally moves in the inside to the back surface side. The rib 186 has a function as a stopper of the frame bearing 181.

  Further, on the front side of the groove 189, a stopper member 183 for limiting the movement of the frame bearing 181 to the front side is provided. The internal height (inner dimension) of the portion of the groove 189 to which the stopper member 183 is attached is low as shown in FIGS. 13 (b) and 13 (c). Therefore, even in the case of the frame bearing 181 which can be rotationally moved in the portion where the stopper member 183 is not attached (see FIG. 13D), the stopper member 183 is attached, so Movement will be limited. Then, by restricting the movement of the frame bearing 181, the movement of the outer member 184 to which the frame bearing 181 is attached is also restricted.

  Further, the stopper member 183 is made of synthetic resin, and is configured as a separate member from the box side rail 178. Further, on the stopper member 183, claws 183a, 183a for hooking on the box side rail 178 are formed at three places at intervals in the front-rear direction. As shown in FIG. 13B, the box side rail 178 is formed with a hole 178a at a position corresponding to the claw 183a. In addition, the claw 183a is urged to be inserted into the hole 178a by the elastic return force it has. The front end (front side) of the stopper member 183 is fixed to the box side rail 178 via a screw 199. In the present embodiment, although the case where the claw 183a and the screw 199 are used in combination is described as an example, the stopper member 183 may be fixed by only the claw 183a, and the stopper member 183 is fixed by only the screw 199 It is also good.

  FIG. 14 is a cross-sectional view showing the configuration of the frame member, the slide rail, and the box side rail, FIG. 15 is a cross-sectional view taken along the line E-E of FIG. (A) is when the frame bearing abuts against the stopper member, and (b) is when the frame member abuts against the box bearing. In FIG. 14, the front side with respect to the paper surface corresponds to the front side of the refrigerator 10, and the back side with respect to the paper surface corresponds to the back side of the refrigerator 10. A frame bearing 181 (see also FIG. 11) attached to the back side of the outer member 184 moves in the groove 189 of the box side rail 178 while rotating in the front-rear direction.

  On the other hand, the outer member 184 itself including the frame bearing 181 is disposed outside the groove 189 of the box-side rail 178 so as to move in the front-rear direction together with the frame bearing 181. That is, the slide rail 179 configured to include the outer member 184 is disposed outside the box side rail 178. In other words, the box side rail 178 and the slide rail 179 are separately disposed in a cross sectional view from the front side in the direction perpendicular to the moving direction of the storage container 101. That is, the box side rail 178 and the slide rail 179 are arranged in the lateral direction so as not to overlap in the cross sectional view.

  Further, as described above, the frame member 180 is fixed to the side surface (inner wall surface) of the inner member 185 by the rivets 187.

  As shown in FIG. 15, the lower surface portion 180c of the frame member 180 is in contact with the box bearing 182 (support) as described above. The box bearing 182 is rotatably attached to the front end of the box side rail 178. Therefore, when the frame member 180 moves in the front-rear direction, the frame member 180 moves in the front-rear direction while rotating the box bearing 182 while being supported by the box bearing 182.

  Returning to FIG. 14, the dimension (length in the vertical direction, inner dimension) L1 of the groove 189 of the box side rail 178 is shorter than the dimension (length in the vertical direction, outer dimension) L2 of the slide rail 179 . That is, in the refrigerator 10, the slide rail 179 having a dimension L2 larger than the dimension L1 of the groove 189 of the box side rail 178 is used. Therefore, regardless of the dimension L1 of the groove 189 of the box side rail 178, the slide rail 179 having a sufficient dimension L2 can be used. Therefore, the rigidity of the slide rail 179 is sufficiently secured, and the local load is prevented from being applied to the slide rail 179. As a result, when the outer member 184 pulls out the inner member 185 after stopping, local increase in frictional force due to local load applied to the balls 188 can be prevented, and the storage container 101 can be pulled out with light force.

  Further, of the inner member 185 and the outer member 184 constituting the slide rail 179, the inner member 185 is fixed to the frame member 180 by the rivets 187. That is, the inner member 185 having a cross-sectional area smaller than the cross-sectional area of the outer member 184 in a cross-sectional view from the front side in the direction perpendicular to the moving direction to the front side and the back side of the storage container 101 Is attached to In addition, the storage container 101 is supported by the frame member 180. As a result, the second moment of area of the inner member 185 and the frame member 180 fixed thereto becomes large, and the load of the storage container 101 is dispersed and applied to the entire frame member 180. Therefore, the occurrence of a large local frictional force is suppressed, and the storage container 101 can be pulled out with a smaller force.

  Here, with reference to FIG. 14 to FIG. 16, an operation of each member when the storage container 101 is pulled out to the front side will be described. In any of the drawings, the storage container 101 is not shown for simplification of the drawing.

  When the storage container 101 is stored in the vegetable compartment 100 (see FIG. 15), the slide rail 179 is most compressed and the rear end 180s of the frame member 180 is closest to the connection member 192 of the outer member 184. As described above, when a force for pulling out the storage container 101 to the front side is applied in the state where the storage container 101 is stored in the vegetable chamber 100, the storage container 101 is moved to the front side of the frame member 180 and the slide rail 179. Movement of is started. The force is applied by pulling the user's hand on the handle of the vegetable compartment door 6 (see FIG. 1) and pulling out the container drive mechanism 200 (see FIG. 6) connected to the connection portion 168 (see FIG. 3). It is done by Further, the application of the force by the container drive mechanism 200 is performed only once at the start of the movement as described above, and thereafter the storage container 101 is pulled out to the front side by inertia.

  At this time, the frictional force generated between the ball 188 constituting the slide rail 179 and the outer member 184 or the inner member 185 is relatively large. On the other hand, the frictional force generated between the frame bearing 181 and the groove 189 and the frictional force generated between the box bearing 182 and the lower surface portion 180c of the frame member 180 are relatively small (see FIG. 14). Therefore, a relatively large frictional force generated as the inner member 185 moves to the front side is also transmitted to the outer member 184 via the ball 188. Thereby, the slide rail 179 (outer member 184) is also moved to the front side along with the movement of the storage container 101 and the frame member 180 (see FIG. 16A).

  When the frame bearing 181 moves while rotating inside the groove 189 of the box side rail 178 to the front side, the frame bearing 181 abuts against the stopper member 183 provided in the groove 189 as shown in FIG. become. Thus, the rotation of the frame bearing 181 is stopped, and the movement of the outer member 184 provided with the frame bearing 181 is also stopped. However, when the ball 188 (see FIG. 14) rotates, the inner member 185 and the frame member 180 which can move independently of the outer member 184 continue to move to the front side together with the outer member 184.

  Then, as shown in FIG. 16 (b), along with the movement of the inner member 185 to the front side, the frame member 180 fixed to the inner member 185 and the storage container 101 supported by the frame member 180 also to the front side. It will continue to move. At this time, the frame member 180 moves to the front side while rotating the box bearing 182 on the box bearing 182. Therefore, when the frame member 180 moves to a predetermined position on the front side (the entire storage container 101 is pulled out from the vegetable compartment 100), the protrusion 176 provided on the rear side lower end portion of the frame member 180 is shown in FIG. It will hit the box bearing 182 as in b). Thereby, the movement of the frame member 180 is stopped. In addition, when the movement of the frame member 180 is stopped, the movement of the storage container 101 is also stopped. This state is a full open state in which the storage container 101 is pulled out to the front as much as possible.

  Further, in the present embodiment, as shown in FIG. 16B, the distance L10 between the rear end 180s of the frame member 180 and the connecting member 192 when the outer member 184 is maximally extended, the frame bearing 181 is a stopper member The distance L 30 is longer than the distance L 20 between the rear end 180 s of the frame member 180 and the connecting member 192 when the projection 176 of the frame member 180 abuts on the box bearing 182. There is. By providing the distance L30 (play) in this manner, when the storage container 101 is fully opened, a strong impact is not applied to the stopper member 183 from the frame bearing 181, so that breakage of the stopper member 183 can be prevented. In addition, when the storage container 101 is pulled out due to a frictional force generated between the frame bearing 181 and the groove 189 or by narrowing the inner dimension of the groove 189 on the way, the inner member 185 and the frame member 180 may be operated to be extended (pulled out).

FIG. 17 is a longitudinal sectional view when the storage container is pulled out to the front side as much as possible.
As shown in FIG. 17, in the fully open state in which the storage container 101 is completely pulled out, the load F of the storage container 101 is supported by two points, the box bearing 182 and the frame bearing 181. In addition, the outer member 184 is disposed between the box bearing 182 and the frame bearing 181 by the length of the stopper member 183 in the front-rear direction. Therefore, the downward load F from the storage container 101 is supported by the portion of the length of the stopper member 183. Therefore, it is possible to prevent a large load from being locally applied to the box bearing 182, and as a result, it is possible to make the force when pulling out the storage container 101 small.

  And since the force at the time of pulling out the storage container 101 can be made small, the magnitude of the force applied by the container drive mechanism 200 (see FIG. 6) connected to the connection portion 168 of the frame 161 is also reduced. Can. Therefore, the load of the motor (not shown) which comprises the container drive mechanism 200 can be reduced. Further, since the storage container 101 is pulled out to the front side with a small force, it is possible to prevent the storage container 101 from being opened to the front side too much.

  By the way, when the storage container 101 is fully pulled out from the vegetable compartment 100 and the stored goods stored in the storage container 101 are heavy, the load F received from the storage container 101 causes the frame member 180 to be moved. The force acts in the direction W (see FIG. 14) in which the inner fall occurs. As a result, a force acts to pull the frame member 180 away from the inner member 185. When the frame member 180 falls inward, the height position of the frame member 180 at the rear end decreases, so the height position at the vegetable compartment door 6 located on the front side becomes even lower, and the vegetable compartment door 6 It goes down. Therefore, in the present embodiment, when the storage container 101 is drawn fully open (full open), the fixing position by the rivets 187 is a region where the inner member 185 and the outer member 184 overlap with each other. It is possible to suppress the inward fall of the rear portion of the frame member 180, and to suppress the lowering of the vegetable compartment door 6.

  In the present embodiment, the fixing portion by the rivet 187A (187) is located on the vertical projection of the box bearing 182, in other words, the position where the box bearing 182 and the rivet 187A (187) overlap in the vertical direction (vertical direction). By disposing in the above, it is possible to suppress the inward fall of the supporting point portion P of the frame member 180. By being able to more reliably suppress the inward fall at the fulcrum portion P, the lowering posture at the position of the vegetable compartment door 6 can be reliably suppressed.

  Further, as described above, when the storage container 101 is fully pulled out of the vegetable compartment 100, if the weight of stored goods stored in the storage container 101 is large, the load F received from the storage container 101 causes A twist (a force to deform the frame member 180 so as to fall inward) is generated with respect to the frame member 180. The twisting of the frame member 180 means that the lower surface portion 180c of the frame member 180 with which the box bearing 182 abuts is deformed as shown by a dashed dotted line S1 (see FIG. 14). As a result, the height position of the frame member 180 at the rear end is lowered, so that the height position of the vegetable compartment door 6 located on the front side is further lowered, and the vegetable compartment door 6 is lowered. .

  Therefore, in the present embodiment, when the storage container 101 is drawn fully open, the rib 180f is positioned on the vertical projection of the box bearing 182, in other words, the box bearing 182 and the rib vertically above the box bearing 182 Disposition of the frame member 180 at the fulcrum portion P can be suppressed by being disposed at a position where it overlaps with 180 f. As described above, since the twisting of the frame member 180 can be suppressed, the inner falling of the frame member 180 can be suppressed, and the lowering of the vegetable compartment door 6 when the storage container 101 is fully open can be suppressed.

  Further, in the present embodiment, by applying a hollow rivet as the rivet 187 for fixing the frame member 180 and the inner member 185, the protrusion from the inner member 185 can be reduced, and the tip of the rivet 187 is the slide rail 179. Contact with the retainer 191 can be prevented, and the bonding strength between the frame member 180 and the inner member 185 can be enhanced as compared to the blind rivet.

FIG. 18 is a side view showing a second embodiment of a fixing method of the frame member and the inner member.
As shown in FIG. 18, the refrigerator of the second embodiment is provided with rivets 187B and 187C for fixing the frame member 180 and the inner member 185. In the second embodiment, when the rivet 187B in the first embodiment is H, the rivet 187B is positioned below the height H, and the rivet 187C is at the height H (see the alternate long and short dash line). Is different from the first embodiment in that it is located at the upper side. In addition, the position of the front-back direction (front-back) of rivets 187B and 187C is the same as that of 1st Embodiment. By displacing the rivets 187B and 187C up and down in this manner, the fulcrum is far from the twisting with respect to the frame member 180, so that the twisting can be reduced. As a result, since the inner falling of the frame member 180 can be suppressed, the falling of the vegetable compartment door 6 can be suppressed.

  Note that the directions of shifting the rivets 187B and 187C up and down may be reversed. Further, one rivet may be set as the center H, and the other rivet may be shifted up or down.

  Further, the rivet at the rear end for fixing the frame member 180 and the inner member 185 may be positioned rearward of the vertical projection of the box bearing 182 when the storage container 101 is pulled out to the maximum. Even with such a configuration, since it is possible to suppress the inward collapse due to the twisting of the frame member 180, it is possible to suppress the lowering of the vegetable compartment door 6.

  In the embodiment described above, the cross frame 167 and the frame bearing 181 are attached to the slide rail 179 via the connecting member 192 as an example, but the cross frame 167 is not provided. And the frame bearing 181 may be directly attached to the slide rail 179.

  Moreover, although the case where the storage container 101 was accommodated in the vegetable compartment 100 was mentioned as the example and demonstrated in the above-mentioned embodiment as an example, if it is a storage container accommodated in the refrigerator 10, what kind of thing is It is also good. In the present embodiment, the inner member 185 having a small cross-sectional area has been described as an example attached to the frame member 180. Conversely, an outer member 184 having a large cross-sectional area is attached to the frame member 180 It may be a configuration.

6 vegetable room door 10 refrigerator 100 vegetable room (storage room)
DESCRIPTION OF SYMBOLS 101 Storage container 102 Lower container 103 Upper container 124 Inner box 161 Frame 168 Connection part 176 Protuberance 178 Box side rail (storage room rail, storage container drawer accommodation mechanism)
179 slide rail (storage container drawer storage mechanism)
180 frame member 180f rib (reinforcement)
181 Frame bearing 182 Box bearing (support, storage container drawer storage mechanism)
183 Stopper member 184 Outer member (storage container drawer storage mechanism)
185 Inner member (storage container drawer storage mechanism)
186 Rib (Stopper)
187 Rivet (storage container drawer storage mechanism)
188 Ball (Roller, storage container drawer storage mechanism)
189 groove 190 guide wall

Claims (4)

A storage room,
A storage container stored in the storage room;
A refrigerator comprising: a storage container drawer storage mechanism for pulling out the storage container from the storage chamber; and storing the storage container in the storage chamber.
The storage container drawer storage mechanism is
Storage chamber rails provided in the storage chamber and extending in the longitudinal direction;
A frame member for supporting the storage container;
The inner member and the inner member extend in contact with both the inner member and the outer member, and the inner member extends along the storage chamber rail, the outer member disposed facing the inner member, and the inner member and the outer member. A slide rail provided with a rolling element that allows the outer member to move independently;
And a support for movably supporting the frame member in the front-rear direction while being in contact with the frame member,
One of the inner member and the outer member is fixed to the frame member;
The fixing portion fixed to the frame member is located in a region where the inner member and the outer member overlap when the storage container is pulled out to the maximum .
At least a part of the fixing portion is located on the vertical projection of the support or behind the support when the storage container is pulled out to the maximum . The frame member, a refrigerator according to claim 1, characterized in that it has a reinforcing part for reinforcing the frame member. The refrigerator according to claim 2 , wherein at least a part of the reinforcing portion is located on a vertical projection of the support when the storage container is pulled out to the maximum. The refrigerator according to any one of claims 1 to 3 , wherein the fixing portion is fixed by a hollow rivet.

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